1. INTRODUCTION
The demand
for making air traveling more 'pleasant, secure and productive for passengers
is one of the winning factors for airlines and aircraft industry. Current
trends are towards high data rate communication services, in particular Internet
applications. In an aeronautical scenario global coverage is essential for
providing continuous service. Therefore satellite communication becomes
indispensable, and together with the ever increasing data rate requirements of
applications, aeronautical satellite communication meets an expansive market.
Wireless
Cabin (IST -2001-37466) is looking into those radio access technologies to be
transported via satellite to terrestrial backbones . The project will provide UMTS services, W-LAN
IEEE 802.11 b and Blue tooth to the cabin passengers. With the advent of new
services a detailed investigation of the expected traffic is necessary in order
to plan the needed capacities to fulfill the QoS demands. This paper will thus
describe a methodology for the planning of such system.
In the
future, airliners will provide a variety of entertainment and communications
equipment to the passenger. Since people are becoming more and more used to
their own communications equipment, such as mobile phones and laptops with
Internet connection, either through a network interface card or dial-in access
through modems, business travelers will soon be demanding wireless access to
communication services.
2.WIRELESS
CABIN ARCHITECTURE
So far, GSM telephony is prohibited in commercial
aircraft due to the uncertain certification situation and the expected high
interference levels of the TDMA technology. With the advent of spread spectrum
systems such as UMTS and W-LAN, and low power pico-cell access such as Blue
tooth this situation is likely to change, especially if new aircraft avionics
technologies are considered, or if the communications technologies are in line
with aircraft development as today
When wireless access technologies in aircraft
cabins are envisaged for passenger service, the most important standards for
future use are considered to be: UMTS with UTRAN air interface, Blue tooth, and
W-LAN IEEE 802.11 b. Of course, these access technologies will co-exist with
each other, beside conventional IP fixed wired networks. The wireless access
solution is compatible with other kinds of IFE , such as live TV on board or provision of
Internet access with dedicated installed hardware in the cabin seats. Hence, it
should not be seen as an alternative to wired architecture in an aircraft, but
as a complementary service for the passengers.
Several
wireless access segments in the aircraft cabin, namely a wireless LAN according
to IEEE 802.11 b standard for IP services, an UMTS pico-cell for personal and
data communications, and Bluetooth1.1, as well as a standard wired IP LAN.
A satellite
segment for interconnection of the cabin with the terrestrial telecom networks.
The different cabin services must be integrated and interconnected using a
service integrator, that allows the separation and transportation of the
services over a single or several satellite bearers. Peculiarities, such as
limited bandwidth, asymmetric data rates on satellite up- and down-link, and
dynamic traffic demand between the different services and handover between
satellite bearers need to be addressed. In order to minimize the cost
(satellite resources) for a given QoS efficient interworking between the
service integrator and the satellite segment will be required.
An aircom
service provider segment supporting the integrated cabin services. The aircom
provider segment provides the interconnection to the terrestrial personal and
data networks as well as the Internet backbone. For the UMTS cabin service, a
subset of the UMTS core network must be available.
The
provision of such a heterogeneous access network with collectively mobile users
requires the development of new protocol concepts to support
·
The
integrated services with dynamic bandwidth sharing among the services and
asymmetrical data rate;
·
IP
mobility and virtual private networks (VPN) for the individual passengers in
the mobile network; authentication, admission and accounting (AAA) in the
mobile network, especially taking into account the necessity to support
different pricing concepts for each passenger in the mobile network and the
interaction of airline, satellite provider, aircom service provider and
terrestrial service providers.
3. SATELLITE CONNECTION
Connection
to telecom networks is considered to be
achieved by satellites with large coverage areas especially over oceanic
regions during long-haul flights. The service concept needs to take into
account today's peculiarities of satellite communications, thus it must cope
with the available or in near future available satellite technology, and
interworking must be performed at aircraft interface level with the satellite
segment,
·
Only
restricted satellite data rates will be available in the near future; thus the
bandwidth that is requested by standard interfaces of the wireless standards
needs to be adapted to the available bandwidth (typically: 432 kb/s in down-
link, 144 kb/s up-link (Inmarsat B- GANTM), or 5 Mb/s in down-link, 1.5 Mb/s in
up-link (Connexion by Boeing)). Furthermore, dynamic bandwidth management is
needed to allocate higher bit rates from temporarily unused services to other
service-
·
Currently,
few geostationary satellites such as the Inmarsat fleet are available for
two-way communications, that cover the land masses and the oceans. Ku-band may
be used on a secondary allocation basis for aeronautical mobile satellite
services (AMSS) but bandwidth is scarce and coverage is mostly provided over continents.
K/Ka-band satellites will be launched in the near future, again here
continental coverage is mainly intended. The scenario must thus consider
§
the
use of different satellite systems, which will probably force the support of
different service bearers, and
§
handover
between satellite systems.
It is assumed that each satellite segment is connected via
terrestrial wide area networks or via the IP backbone to the aircom service
provider.
·
Asymmetrical
data rates in satellite up- and down-links, that may also be caused to operate
in conjunction with different satellites systems for up- and down-link. The
service portfolio in the cabin and the service integration needs to cope with
this possibility.
4. TECHNICAL OVERVIEW
A. UMTS
The Universal
Mobile Telecommunication System (UMTS)
is the third generation mobile communications system being developed
within the IMT -2000 framework. UMTS will build on and extend the capability of
today's mobile technologies (like digital cellular and cordless) by providing
increased capacity, data capability and a far greater range of services.
In January
1998, ETSI reached an agreement concerning the radio access technique to be
used for UMTS. This air interface, named UTRAN (UMTS Terrestrial Radio Access)
is applicable in the two existent duplexing schemes for UMTS: UMTS-FDD and
UMTS- TTD. UMTS-FDD relies on wideband-CDMA (W-CDMA) access technique, while
UMTS- TTD uses the TD-CDMA access technique, a combination of CDMA and TDMA
technologies.
a) Umts Structure
B. BLUETOOTH
Bluetooth
operates in the unlicensed 2.4--GHz ISM (industrial, scientific and medical)
band and uses a frequency- hopping spread spectrum (FHSS) technique to minimise
interference. A Bluetooth unit has a nominal range of approximately 10 meters
(in the Class 3 defined in the standard, but which can be enlarged by
amplifying the transmit power in Class 2 and Class 1 up to 100 m.). Two or more
Bluetooth units sharing the same channel form a piconet. Each piconet consists
of a master unit and up to seven active slave units. Furthermore, two or more
piconets can be interconnected to form a scattemet. To be a part of more than
one piconet a unit called inter-piconet unit (gateway) is required.
c. IEEE802.11b
Wireless
local area networking (WLAN) radio technology provides superior bandwidth
compared to any cellular technology. The IEEE 802.11 b standard offers a
maximum throughput of II Mbps (typical 6.5 Mbps) working in the same 2.4- GHz
ISM band as B1uetooth by the use of direct sequence spread spectrum (DSSS).
WLANs were originally intended to allow local area network (LAN) connections
where premises wiring systems were inadequate to support conventional wired
LANs, but they were later identified with mobility.
A WLAN cell
is formed by an AP and an undefined number of users in a range from
approximately 20 to more than 300 m ( 100 m. in indoor environments) that
access the AP through network adapters (NAs ), which are available as a PC card
that is installed in a mobile computer.
Table 1
summarizes the main parameters of each standard, where only Class 3 of the
Bluetooth standard has been considered, as long as the Bluetooth version 1.0
specification focuses primarily on the 10- meter ranger standard radio. Notice
that the coverage range in the UMTS case is capacity dependent and it can vary
from 200 m. up to 1.4 Km., a phenomena known as "cell breathing".
|
|
Bit rates
|
Bw.(MHz)
|
Band(GHz)
|
Coverage
Range(m.)
|
Duplexing
Scheme
|
Tx.P.
(dBm)
|
Modulation
|
|
|
Max
|
Typ
|
|||||||
UMTS |
2Mbps
|
144Kbps
|
5,10,20
|
FDD:
1.92-1.90(ul)
2.11-2.17(dl)
TDD:
1.90-1.92
2.01-2.025
|
Depends on capacity
|
FDD/TDD
|
20
|
QPSK(dL)
BPSK (uL)
|
|
Bluetooth
|
1Mbps
|
728 Kbps
|
1
|
2.4-2.4835
|
10
|
TDD
|
0
|
GFSK
|
|
IEEE
802.11b
|
11Mbps
|
6,5Mbps
|
26
|
2.4-2.4835
|
20-100
|
TDD
|
20
|
Depends on bit rate
|
5. SERVICE
INTEGRATOR
The
different wireless access services of UMTS, W-LAN and Bluetooth require an
integration of the services over the satellite. The central part of the service
portfolio provisioning is the service integrator (SI), cf. Figure 3. The
service integrator will provide the interfaces for the wireless and wired
service access points in the cabin, as well as the interface to the terrestrial
networks at aircom provider site. All services will be bundled and transported
between a pair of Service Integrators. It performs the encapsulation of the
services and the adaptation of the protocols.
The SI
multiplexer is envisaged to assign variable capacities to the streams,
controlled by a bandwidth manager that monitors also the QoS requirements of
the different service connections. Changes in capacity assignment must be
signaled to the SI at the other communication end. The heterogeneous traffic
stream is then sent to streaming splitter/combiner. This unit is envisaged to
support several satellite segments and to perform handover between them.
Asymmetrical data rates in inbound and outbound directions can be managed here.
Adaptation to the supported satellite segments are done by medium access controllers
(MAC) in a modular manner. Towards the terminal side, the interfaces of the
wireless access standards need to interwork with the transport streaming of the
SI by specific adaptation layers (AL). These ALs have to be designed according
to the analysis of the impact of delay, jitter and restricted / variable
bandwidth on the protocol stack. Buffering (to compensate delay jumps at
handover) and jitter compensation for real-time services (e.g., voice) must be
also provided here.
6. SERVICE DIMENSIONING
This
section provides an overview of key issues and steps for the systematic system
dimensioning of Wireless Cabin aircom satellite communications system. We will tackle the satellite constellations
as potential candidates for aircom services as well as the gross traffic
calculation and assignment process.
Different
market entry options and reference business cases must be taken into account in
an initial stage of a system design.
The evolutionary path leads from existing L-band systems such as
inmarsat GAN (see Figure 5) or
B-Gan in few years up to C/Ku band and existing GEO transponders, whereas the “revolutionary” path may target from the beginning at advanced K/Ka band technology and the design of a tailor-made, potentially non-GEO system.
B-Gan in few years up to C/Ku band and existing GEO transponders, whereas the “revolutionary” path may target from the beginning at advanced K/Ka band technology and the design of a tailor-made, potentially non-GEO system.
The system dimensioning process can be
structured in several steps:
·
Determination of gross traffic
per aircraft using the multi-service model
·
Determination of the timely and
locally varying traffic, depending on the flight path and flight schedule,
assuming also a service rool-out scenario for different airlines and aircraft
types.
·
Identification of potential
serving satellites and their coverage areas.
·
Mapping and traffic allocation
of the aircom traffic to the satellite systems.
Two key observations
concerning the “geographic market” are 1) the pronounced asymmetry of market
opportunities between northern and southern hemisphere (partly just a result of
our earth’s “continental layout”), and the fact
that a significant share of the
addressable market is at higher (northern ) latitudes, especially with the
important long-haul intercontinental flight routes between the European, North
American and East Asian regions. Both
observations are illustrated in figure 6, although its view is Europe-centric;
the underlying flight route investigations have been performed within the
European ACTS project ABATE and have been used for design and dimensioning
studies of an aeronautical subsystem of the EuroSkyWay satellite communications
system
7.
INTERFERENCE
Once the
above described measurements finish. four types of interferences within the
CMHN have to be studied: the co-channel interference among the terminals of the
same wireless access segment, the inter- segment interference between terminals
of different wireless networks, the cumulative interference of all simultaneous
active terminals with the aircraft avionics equipment and the interference of
the CMHN into terrestrial networks.
From the
co-channel interference analysis the re-use distance and the re-use frequency
factor for in-cabin topology planning will be derived. For this reason it is
important to consider different AP locations during the measurements.
It is not
expected to have major problems due to interference from UMfS towards WLAN and
Bluetooth, thanks to the different working frequency. On the other hand,
particular interest has to be paid in the interference between Bluetooth and
WLAN .Due to the market acceptance of Bluetooth and WLAN, there is a special
interest of designers and portable data devices manufacturers to improve the
coexistence of the two standards. There are many studies showing the robustness
and the reliability of Bluetooth in presence of WLAN and vice versa.
A
description of the electromagnetic behaviour of conventional aircraft equipment
is necessary to analyse the interference and the EMC of the new wireless
network with the avionics systems. The allowed radiated field levels are
regulated and must be respected if certification is desired. So far, GSM
telephony is prohibited in commercial aircraft due to the uncertain
certification situation and the expected high interference levels of the TDMA
technology. With the advent of spread spectrum systems such as
8. COLLECTIVELY MOBILE
HETEROGENEOUS NETWORK
The concept
of having several users, which are collectively on the move forming a group
with different access standards into this group, is called Collectively Mobile
Heterogeneous Network (CMHN). In such a scenario [5] one can find two types of
mobility and two types of heterogeneity: the mobile group itself and the user
mobility inside the group from one side, and heterogeneous access segments and
heterogeneous user access standards from the other side. The aircraft cabin
represents a CMHN (see Fig. 1) supporting three types of wireless (user
mobility) access standards (heterogeneous user access) inside an aircraft (the
mobile group) using one or more satellite access segments. The CMHN may cross
coverage areas and then inter-/ intra- satellite handover will be required. The
communication infrastructure to support the cabin CMHN is depicted in Fig 2.
The architecture consists of (i) several wireless access segments in the
aircraft cabin which can coexist with the standard wired IP LAN, (ii) a satellite
segment for interconnection of the cabin with the terrestrial telecom networks,
and (iii) an aircom service provider segment supporting the integrated cabin
services.
9.CONCLUSION
Go meet the
increasing and ever changing needs of the most demanding passengers a solution
in which passengers, both business and economy, could use their own wireless
equipment must be developed. This approach has many advantages. From the users
point of view, their service acceptance will be increased by the following
facts: they can be reached under their usual telephone number, they may have
available telephone numbers or other data stored in their cell phones or PDAs,
their laptops have the software they are used to, the documents they need and
with their personalized configuration (starting web site, bookmarks, address
book). In addition, since users in an aircraft are passengers, the electronic
devices they carry with them is wireless, like laptops with WLAN interface.
From the airlines point of view there is a huge saving of the investment that
would suppose the installation of terminals (screens, stations, wired
telephones), the consequent software licenses (in case of PCs) and the further
investment due to hardware updating to offer always last technology to their
customers. Currently, one of the major IFE
costs is due to film copies and delivery expenses of new movies. This could be
reduced if other broadband services were offered to passengers via satellite.
Anyway, the wireless access solution is not replacing other kinds of IFE , such as TV on board
or provision of Internet access with dedicated installed hardware in the cabin
seats. Hence, it should not be seen as an alternative to a wired architecture
in aircraft, but as an added service for passengers.
10.
REFERENCE
·
Passenger Multimedia Service
Concept Via Future Satellite System
By A. Jahan, M. Holzbock
Institute of Communication and Navigation,Germany
By A. Jahan, M. Holzbock
Institute of Communication and Navigation,
·
IEE Communication Magazine,
July 2003
·
www.inmarsat.com/swift64
·
www.wirelesscabin.com
·
Wireless mobile communication
by William Feher
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